A method for forming a projectile cartridge includes positioning a sabot within a compartment of a projectile cartridge casing. A delivery tube is inserted within a chamber of the sabot positioned within the casing, the delivery tube bounding a channel that passes therethrough. A projectile comprised of an elastomeric material is passed through the channel of the delivery tube under a pressurized gas so that at least a portion the projectile is received within the chamber of the sabot, the projectile being radially compressed as it is passed through the channel of the delivery tube.
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1. A method for forming a projectile cartridge comprising:
positioning a sabot within a compartment of a projectile cartridge casing;
inserting a delivery tube within a chamber of the sabot positioned within the casing, the delivery tube bounding a channel that passes therethrough; and
passing a projectile comprised of an elastomeric material through the channel of the delivery tube so that at least a portion the projectile is received within the chamber of the sabot, the projectile being radially compressed as it is passed through the channel of the delivery tube.
2. The method as recited in
3. The method as recited in
4. The method as recited in
5. The method as recited in
6. The method as recited in
7. The method as recited in
8. The method as recited in
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The present application is a divisional of U.S. application Ser. No. 11/927,216, filed Oct. 29, 2007, which claims priority to U.S. Provisional Patent Application No. 60/854,993, filed Oct. 28, 2006, which are incorporated herein by specific reference.
1. The Field of the Invention
The present invention relates to sabots used with elastomeric projectiles, projectile cartridges containing an elastomeric projectile, and methods and systems for making projectile cartridges containing an elastomeric projectile.
2. The Relevant Technology
Sabots are commonly used within shotgun shells and some rigid bullet cartridges to provide a gas seal between the exploding propellant and the projectile and to stabilize the projectile during the firing process. A typical sabot used in shotgun shells comprises a tubular sleeve that bounds a compartment and has a floor formed at one end thereof. Spaced apart, longitudinal slits are formed on the sleeve at the end opposite the floor so as to form a plurality of leaves. The sabot is positioned within the outer shell above the exploding propellant and the projectile or shot is positioned within the compartment of sabot. When the shell is fired, the projectile and sabot concurrently travel down the length of the shotgun barrel. As the sabot exits the barrel, the leaves on the sabot radially, outwardly expand causing the sabot to slow and separate from the projectile. Sabots have been used for single body projectiles such as slugs, bullets and fin stabilized darts or rockets. In these alternative embodiments, the sabots can either separate from the projectile directly after exiting the barrel or become part of the projectile to increase the desired aerodynamic properties.
Although conventional sabots are useful in the launching of standard projectiles as discussed above, conventional sabots are not designed for use with elastomeric projectiles. Elastomeric, non-lethal projectiles are projectiles made from a flexible, elastomeric material that expands on impact to debilitate a recipient but not produce terminal injury. However, due to the unique properties of elastomeric projectiles, such projectiles can be difficult to load into conventional sabots and conventional sabots can impede the discharge or trajectory of such projectiles.
Furthermore, the prior art encompasses numerous methods and machines for loading projectiles. However, such prior art methods and machines are not designed for loading very elastic projectiles of high surface friction where the diameter of the projectile is larger than the diameter of the shell into which it is being loaded.
Various embodiments of the present invention will now be discussed with reference to the appended drawings. It is appreciated that these drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope.
Depicted in
Upon ignition of charge 44 by primer 42, the expanding gas produced by charge 44 pushes against gas seal wad 14 which in turn drives sabot 16 and enclosed projectile 18 out of casing 12 and down the length of the gun barrel. Once sabot 16 and enclosed projectile 18 exits the end of the gun barrel, sabot 16 openly expands casing separation between projectile 18 and sabot 16. Projectile 18 then freely travels to the final target.
With regard to projectile 18, in one embodiment projectile 18 comprises a non-lethal projectile having a substantially spherical shape with a diameter larger than the width of casing 12. Projectile 18 is capable of striking a target with a large amount of kinetic energy while maintaining a low pressure spike. Projectile 18 can accomplishes this feat in two ways. First, projectile 18 is made of a sufficiently resilient material as to deform upon impact. The deformation happens along the radius of projectile 18, which becomes larger and flatter, thus reducing the imparted force per unit area. Second, projectile 18 absorbs a quantified amount of energy within its molecular structure while accommodating this new deformed state. As used herein, the term “pressure spike” refers to pressure plotted over time. Thus, with a lower pressure spike, the energy is distributed over a greater period of time than with a high pressure spike.
Projectile 18 is typically comprised of a low durometer polymeric material, or a combination of a low durometer polymeric material and a relatively higher durometer polymeric material, and a heavy-metal powder that is homogeneously dispersed therein. In one embodiment, the low durometer material is a thermoplastic elastomer (TPE) with a density ranging from 0.86 to 0.90 grams per cubic centimeter, and the metal powder is tungsten, which has a specific gravity (S.G.) of 19.3. Optionally, natural rubber can be added to the TPE to increase resiliency. In alternative embodiments, the TPE can have a density ranging from about 0.8 grams per cubic centimeter to about 1.2 grams per cubic centimeter with about 0.80 grams per cubic centimeter to about 0.90 grams per cubic centimeter being more common. Other densities can also be used. The TPE typically has a durometer in a range between about 30 Shore 00 to about 30 Shore A with about 30 Shore 00 to about 15 Shore A being more common. Other values can also be used. Other metal powders that can be used are rhenium (S.G. 21), lead (S.G. 11.35), bismuth (S.G. 9.781), copper (S.G. 8.94), nickel (S.G. 8.9), iron (S.G. 7.87), and zinc (S.G. 7.13). Tungsten is a desirable metal because of its relatively high specific gravity; if tungsten were not used, the volumetric ratio of metal powder to TPE would increase, which in turn could compromise the strength of the composite material. In one embodiment, the particle size of the tungsten is in a range from about 50 microns to about 250 microns. Other particles sizes can also be used. Although the specific gravity of rhenium is greater than that of tungsten, the price of rhenium is currently prohibitive for its use in the present invention.
Alternatively, instead of using only a single low durometer material, the projectile of the present invention may be comprised of a low durometer material combined with a relatively higher durometer material. In this embodiment, the metal powder is evenly distributed throughout the relatively higher durometer material, which in turn is then combined with the lower durometer material to form projectile 18. The relatively higher durometer material may be a natural rubber, a polyurethane, or a thermoplastic elastomer with a durometer preferably in the range of 0 Shore A to 80 Shore A.
One common material hardness or durometer for the composite material is less than 30 Shore A or less than 15 Shore A or in a range from about 30 Shore 00 to about 30 Shore A with about 30 Shore 00 to about 15 Shore A being more common. Other values can also be used. One common density of the composite material is from about 1.5 grams per cubic centimeter to about 9.5 grams per cubic centimeter with about 1.5 grams per cubic centimeter to about 5.0 grams per cubic centimeter being more common. Other vales can also be used. The weight of the projectile is typically in the range of about 15 grams to about 100 grams with about 15 grams to about 50 grams being more common. Common diameters for projectile 18 are typically in a range of about 10 mm to about 40 mm with about 15 mm to about 30 mm being more common. One common TPE for the low durometer material (whether used with or without the relatively higher durometer material) is styrene-ethylene-butadiene-styrene (SEBS) base polymer, but other TPE variations or elastomers can be used as long as they posses the desired durometer.
In a first embodiment depicted in
The diameter DP of projectile 18 is typically about 20 percent to about 100 percent larger than the diameter DC of casing 12 (
Projectile 18 typically has a spherical configuration so that no specific orientation is required during loading or discharge. In alternative embodiments, however, projectile 18 can have alternative configurations such as a bullet shape or oblong configuration.
With reference to
For most applications, the desired energy level for projectile 18 upon exit from the gun barrel will be in the range of 120 to 200 joules. In applications where projectile 18 is intended to be considered “non-lethal,” projectile 18 must not leave a hole deeper than 44 millimeters in calibrated ballistic clay as per current standards. In one example of the present invention, projectile 18 exits a gun barrel with an average of 166.17 joules and penetrates average calibrated ballistic clay to a depth of 41 millimeters. However, it is appreciated that projectile 18 can be used in a variety of different situations where projectile 18 may not be considered non-lethal. For example, large diameter projectiles 18 can be used for breaking down a door or for otherwise providing a large, blunt force against an inanimate object. In such cases, projectile 18 can be propelled at significantly higher levels of energy.
Returning to
Tubular sleeve 30 has an interior surface 34 that extends between a first end 36 and an opposing second end 38. Interior surface 34 bounds a substantially cylindrical chamber 40. Sleeve 30 can be comprised of plastic, metal, paper, or the like, such as those used in conventional shotgun shell casings. In one embodiment, sleeve 30 can have a length in a range between about 4 cm to about 8 cm with a diameter in a range between about 1 cm to about 4 cm. Other dimensions can also be used. Base 32 is mounted on second end 38 of sleeve 30 so as to close the opening of sleeve 30 thereat and is typically comprised of brass, steel or other suitable material. Primer 42 can comprise primers used in conventional shotgun shell casings and is centrally mounted on base 32 so as to extend therethrough. Positioned adjacent to base 32 within chamber 40 is charge 44 that is typically comprised of gun powder.
During assembly of cartridge 10, gas seal wad 14 is positioned within chamber 40 of casing 12 adjacent to charge 44. Part of the function of gas seal wad 14 is to contain the expanding gas from charge 44 behind gas seal wad 14 so as to maximize the drive force on wad 14, sabot 16 and projectile 18. As depicted in
As depicted in
Returning to
Floor portion 86 projects from interior surface 88 at second end 94 of sidewall portion 84. Floor portion 86 includes an interior surface 106 and an opposing exterior surface 108 that each extend between an inside edge 110 and an opposing mounting edge 112. Inside edge 110 is curved and laterally extends along interior surface 88 of sidewall portion 84 between side edges 96 and 98. Floor portion 86 inwardly projects from sidewall portion 84 so as to form an inside angle θ between interior surface 88 of sidewall portion 84 and interior surface 106 of floor portion 86 that is less than 160° and is typically in a range between about 90° to about 160°. In the depicted embodiment, floor portion 86 slopes down and away from sidewall portion 84 so that inside angle θ is more commonly in a range between about 110° and 160°. Other angles and ranges can also be used.
Petals 82B and 82C are substantially identical to petal 82A except that in contrast to having lips 100 outwardly projecting from side edges 96 and 98, petal 82B includes lip 100 projecting from side edge 96 and a complimentary recess 102 (
Base 80 has a substantially triangular configuration with three linear side edges 104A, 104B and 104C. Mounting edge 112 of each petal 82 is pivotably connected to a corresponding side edge 104 of base 80. In one embodiment, each mounting edge 112 is mounted to a corresponding side edge 104 of base 80 by a living hinge 105. In this embodiment, base 60 and each of petals 82 are integrally molded as a unitary member from a polymeric or other suitable material. As a result of the hinged connection between base 80 and the petals 82, sabot 16 can be selectively moved between a collapsed position as shown in
In the collapsed position as shown in
As previously discussed, projectile 18 remains within compartment 126 of sabot 16 as projectile 18 and sabot 16 travel along the length of the gun barrel. Due to the flexible nature of projectile 18, projectile 18 seeks to compress along the axis of the gun barrel and radially outwardly expand orthogonal thereto as projectile 18 accelerates within the gun barrel. Due to this radial expansion, if there are any openings formed through sidewall 124 of sabot 16, projectile 18 will expand out through the opening and rub along the interior surface of the gun barrel. Engagement between projectile 18 and the interior surface of the gun barrel causes a portion of projectile 18 to rub off onto the interior surface of the gun barrel which in turn gums up the interior surface of the gun barrel. Such deposit of projectile 18 on the interior surface of the gun barrel either prevents or hampers further discharge of projectiles out of the gun barrel until the gun barrel is cleaned.
As also depicted in
As depicted in
Floor 138 has a configuration substantially complementary to recessed pocket 54 on top surface 48 of gas seal wad 14 (
Sabot 16 is originally molded in the expanded position as depicted in
The above configuration for sabot 16 has a number of advantages over conventional sabots. For example, because living hinges 105 about which petals 82A-C pivot are formed on floor 138. The entire length of petals 82A-C are able to fold away from projectile 18 to facilitate ease in separation between sabot 16 and projectile 18. This is in contrast to many conventional sabots where the petals only fold back at the upper end of the sabot and a significant portion of the projectile remains with the compartment of the sabot. Furthermore, unlike conventional sabots where open slots are formed on the sidewall of the sabot, the sidewall of sabot 16 is closed when in the collapsed position so that projectile 18 cannot expand out through the sidewall. In addition, unlike conventional sabots, sabot 16 enables gas to pass through the floor of the sabot and to travel up the full length of the exterior surface of the sabot so that gas can be removed from the compartment of sabot 16 during loading of projectile 18.
As also depicted in
As a further function, most gun barrels have rifling which comprises small, helically grooves that extend the length of the gun barrel. The rifling causes the projectile to spin as it travels the length of the gun barrel. Spinning of the projectile improves the consistency and accuracy of the projectile trajectory. As ribs 140 engage the rifling of the gun barrel, sabot 16 rotates within the gun barrel which in turn causes the rotation of projectile 18. Outwardly projecting ribs 140 can more easily engage the rifling than a sabot with a smooth exterior surface. As such, ribs 140 improve spin and trajectory of projectile 18. In alternative embodiments it is appreciated that ribs 140 need not laterally extend along petals 82 but can alternatively or in combination extend longitudinally along the length of petals 82 or at any desired angle. Furthermore, ribs 140 can be replaced with other forms of projections such as domed or other shaped points that are spaced apart and formed on the exterior surface of each petal 82.
As sabot 16 travels along the length of the gun barrel, friction between the gun barrel and sabot 16 causes sabot 16 to decelerate within the gun barrel. As sabot 16 decelerates, projectile 18 within sabot 16 tries to separate from sabot 16 while it is still within the gun barrel. Early separation of projectile 18 from sabot 16 within the gun barrel can cause projectile 18 to rube against the interior surface of the gun barrel as discussed above and can also significantly affect the trajectory of projectile 18. Accordingly, in one embodiment of the present invention, means are provided on the interior surface of petals 82A-C for engaging projectile 18 when projectile 18 is disposed within chamber 126 of sabot 16. By way of example and not by limitation, as depicted in
In alternative embodiments of the means for engaging projectile 18, it is again appreciated that ribs 142 can be replaced with a variety of different shapes and layouts of projections that extend from interior surface 88 of each petal 82 so as to engage projectile 18. For example, ribs 142 can be replaced with spikes or a variety of other circular, polygonal, or irregular projections extending from interior surface 88 of each petal 82. Furthermore, to help ensure that projectile 18 spins concurrently with sabot 16 within the gun barrel and does not merely slip within sabot 16, ribs or other forms of projections can be formed on interior surface 88 of petals 82 that extend longitudinally along the length of petals 82. Other shapes and configurations of projections can also be used.
Sabot 16 is typically made of a material that is flexible, strong, and has a low coefficient of friction so as to not leave residue within the gun barrel. Preferred materials include polymeric materials such as polyethylene or nylon, although other materials can also be used.
Depicted in
Turning to
Depicted in
An upper plate 210 is slidably mounted on guide rails 196 adjacent to upper frame 192. A plunger 212 is mounted on upper plate 210 and downwardly projects therefrom. Again, means are provided for selectively raising and lower plunger 212 along guide rails 196. One example of such means includes pneumatic cylinder 214 having a shaft 216 that can selectively raise and lower upper plate 210 with plunger 212 mounted thereon. Alternative examples for pneumatic cylinder 204 are also applicable to pneumatic cylinder 214.
Loading system 190 further includes a central plate 220 that is fixedly secured to guide rails 196 between upper plate 210 and lower plate 198. Centrally mounted on central plate 220 is a support housing 222 and a delivery tube 224. As depicted in
As shown in
Returning to
In the assembled configuration, channel 250 of inlet tube 238 couples with channel 266 of dispensing tube 240 so as to form a continuous channel 270 that extends from first end 246 of delivery tube 224 to second end 264 of delivery tube 224. During use projectile 18 can be passed down through continuous channel 270 for delivery of projectile 18 into cavity 234 of support housing 222. As perhaps best illustrated in
To facilitate loading of projectile 18, gas seal wad 14 and sabot 16 are initially positioned within chamber 40 of cartridge 10. Next, base 32 of the assembled casing 12 is seated within socket 202 of stand 200 of loading assembly 190. As shown in
Next, to facilitate loading of projectile 18, projectile 18 is dusted with a dry powder lubricant such as graphite, polytetrafluoroethylene (which is sold under the trademark TEFLON), or other conventional dry lubricants. In one embodiment, the dry lubricant comprises a combination of graphite and TEFLON powders. Projectile 18 is then positioned within channel 270 at first end 246 of delivery tube 224.
As depicted in
In one embodiment of the present invention means are provided for at least substantially sealing the first end of delivery tube 224 closed after projectile 18 is positioned within channel 270. One example is such means comprises upper plate 210 in conjunction with annular seal 217. In alternative embodiments, plunger 212 is not required so that upper plate 210 can be replaced with any type of stop, plug, or cover that will close off the first end of delivery tube 224.
Plunger 212 is designed having configuration that is generally complementary to the interior surface of delivery tube 224 but is sized slightly smaller than the interior surface of delivery tube 224 so that when plunger 212 is fully received within delivery tube 224, an annular gap 272 is formed between the interior surface of delivery tube 224 and the exterior surface of plunger 212 along the length of plunger 212. Gap 272 allows a gas to pass therebetween.
As shown in
Once in the assembled state shown in
As depicted in
Gas supply 280 and the examples herein of how it couples with channel 270 are examples of means for delivering a pressurized gas to channel 270 of delivery tube 224 so that the pressurized gas can push projectile 18 down through delivery tube 224 and into the chamber of the casing 12 when projectile 18 is positioned within delivery tube 224. In alternative examples of such means, the gas can be delivered through plunger 212 or through the side of delivery tube 224.
Once casing 12 is removed from support housing 222, first end 36 of casing 12 can be closed by position overshot card 20 (
It is appreciated that loading system 190 can be made in a variety of different configurations and can be operated in a variety of different manners. By way of example and not by limitation, plunger 212 (
Furthermore, support housing 222 primary functions as a guide for directing casing 12 as sabot 16 receives stem 256. As such, housing 222 need not completely encircle casing 12 and, in some embodiments, housing 222 can be eliminated. Likewise, although loading system 190 is shown as comprising a multitude of parts that are secured together, it is appreciated that many of the parts that are secured together can be integrally formed as a single part or as fewer parts than presently depicted.
Finally, the present embodiment depicts loading system 190 where central plate 220 is stationary while lower plate 198 and upper plate 210 move relative thereto. In alternative embodiments, different plates can be designed to move while others are held stationary. For example. Lower plate 198 can be held stationary while central plate 220 and upper plate 210 are lowered. Alternatively, all three plate can be designed to move. It is appreciated that a variety of other non-essential modification can be made and still achieve the objective of the invention. For example, plates 198, 210 and 220 can have a variety of different configurations and can be used with a different number of guide rails 196. Likewise, guide rails 196 can be eliminated whether other centering mechanisms are used.
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
Kolnik, Joseph P., Elsom, George M.
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